Hypertension - Atrial Fibrillation Clinical Trial
Official title:
Association Between Circadian Blood Pressure Patterns With Asymptomatic Episodes of Paroxysmal Atrial Fibrillation in Hypertensive Subjects
The goals of our study are to determine a).the association between abnormal circadian BP and the development of paroxysmal AF in hypertensive patients, b).at which level of TOD, paroxysmal AF episodes are detected in hypertensive subjects, c).if there is any association between systolic and/or diastolic BP levels with AF occurrence, d).whether the mean heart rate during a 24-hr interval is associated with the development of paroxysmal AF, and finally e).examine the relationship between a wide PP and asymptomatic AF episodes in patients with HTN.
Atrial fibrillation, also known as AF or Afib, is an abnormal and irregular heart rhythm in
which electrical signals are generated chaotically throughout the upper chambers (atria) of
the heart. According to the NICE clinical guidelines, a patient who experiences recurrent
(two or more) AF episodes that terminate spontaneously without any treatment in less than
seven days, and usually within 48 hours is classified as having paroxysmal AF. It has been
shown that paroxysmal AF comprises approximately between 25% and 62% of cases of AF, and it
is estimated that both its incidence and prevalence are likely to rise as the worldwide
population ages dramatically over the next twenty years. Interestingly, hospitalizations due
to AF have increased sharply in the US during the last decade, posing thereby a heavy
economic burden on the health care system and society.
Likewise, hypertension (HTN) also constitutes a major public health problem globally, and
its prevalence is set to increase owing to widespread population ageing. This
epidemiological trend is especially prevalent in rapidly developing countries where early
routine screening at any point of health care is underutilized among risk subjects, due to
several perceived barriers. Moreover, HTN awareness is critical for optimal BP control since
under-diagnosis, under-treatment and/or un-treatment of high BP levels can have deleterious
effects on the cardiovascular system. In addition, HTN is the single most important risk
factor for cerebrovascular stroke, and it has been clearly demonstrated that it is also
associated with structural and functional changes in the myocardium that favor the
development of AF, further increasing the risk of thromboembolism. Among those alterations,
left ventricular hypertrophy (LVH), impaired ventricular filling, left atrial enlargement
and slowing of atrial conduction velocity have been identified as important heralds of
cardiovascular morbidity and mortality. More specifically, since HTN and AF are two
conditions that often co-exist, especially in patients with advanced age, the risk for
considerable morbidity and mortality is increased even more, which points towards the
significance that optimal BP control holds in the prevention of cardiovascular events. To
our knowledge, in the Framingham Heart Study, after controlling for age and other
predisposing conditions, HTN and diabetes emerged as the only cardiovascular risk factors
predicting AF.
It has also been suggested that nocturnal HTN and non-dipping of BP during sleep are
distinct entities that often occur together and are regarded as important harbingers of poor
cardiovascular prognosis. Recently, Pierdomenico et al., showed that non-dipper sustained
hypertensives have a two-fold greater risk of developing AF than dipper ones. This may be
due to the fact that nighttime HTN may be a powerful determinant of long-standing left
ventricular diastolic dysfunction, which subsequently increases atrial stretch. Furthermore,
it has been observed that nighttime hemodynamics, are associated with higher sympathetic and
reduced vagal activity, which may trigger AF. Additionally, sympathetic activation is
associated with the stimulation of the renin-angiotensin-aldosterone axis (RAAA), which
leads to increased left ventricular diastolic preload, both atrial and ventricular fibrosis,
exerting thus direct cellular electrophysiological effects. Besides, scientists suggested
that nighttime HTN is better associated with cardiovascular target organ damage (TOD) as
compared with the non-dipping pattern.
According to the most recent guidelines of the ESH, the presence of microalbuminuria,
increased pulse wave velocity, LVH on echocardiogram and carotid plaques detected during
carotid ultrasonography, constitute markers of asymptomatic organ damage and it has been
clearly demonstrated from multiple studies that they can predict CV mortality independently
of SCORE stratification.
In our study we will try to investigate whether abnormalities in the circadian rhythm of BP
(such as extreme dipping or non-dipping pattern, and/or morning surge) in hypertensive
subjects with or without TOD are associated with the development of new-onset paroxysmal AF.
24-hr ambulatory BP monitoring (ABPM) along with the 24-hour blood pressure monitors with AF
detector will help us to examine the incidence of AF in extremely dippers or non-dippers,
and/or patients exhibiting a morning surge in BP, with or without TOD. Some of the questions
that we aim to answer while conducting this study are whether an asymptomatic AF episode is
more commonly detected in extreme dippers, non-dippers, or morning surgers, during daytime
or during nighttime, or whether TOD is associated with asymptomatic AF episodes.
Importantly, Iqbal et al, demonstrated that there is an association between AF and nighttime
DBP. On top of that, during the past decade, a research study conducted in 546 hypertensive
subjects aged < 60 years of age and who were followed-up for 9.2 years, showed that DBP,
whether 24-hr mean, daytime mean, or nighttime mean, provided the most incremental value for
the prediction of morbid events. Thereby, we want to examine if AF episodes have any
association with the 24hr systolic and the diastolic blood pressure (DBP) levels. It would
also be interesting to observe for any associations between AF occurrence and the mean 24-hr
ABPM and office heart rate (HR).
Moreover, it has been showed that pulse pressure (PP) determines left atrial enlargement in
non-dipper patients with never-treated essential HTN. Thus, in our study, we will also
examine whether a wide PP is associated with silent AF episodes in treated hypertensive
subjects.
Summarizing, the goals of our study are to determine a).the association between abnormal
circadian BP and the development of paroxysmal AF in hypertensive patients, b).at which
level of TOD, paroxysmal AF episodes are detected in hypertensive subjects, c).if there is
any association between systolic and/or diastolic BP levels with AF occurrence, d).whether
the mean heart rate during a 24-hr interval is associated with the development of paroxysmal
AF, and finally e).examine the relationship between a wide PP and asymptomatic AF episodes
in patients with HTN.
Study Population We will evaluate all adult patients referred by their family physicians to
the "Hypertension and Cardiovascular Prevention" Outpatient Clinic at Evangelismos General
Hospital in Athens, from June 2015 to present.
All patients with an average office systolic BP ≥140 mmHg and/or an average diastolic BP ≥90
mmHg on three consecutive visits are considered as having essential HTN. Furthermore,
individuals under treatment with one or more antihypertensive drug are also enrolled in the
study.
Objectives Primary endpoint
• To investigate whether nighttime BP patterns (extreme dipping, normal dipping or reduced
dipping and non-dipping including risers) or early morning surge are associated with the
detection of paroxysmal AF in hypertensive subjects.
Further definitions Normal diurnal systolic and diastolic BP pattern: arterial BP has a
daily variation characterized by substantial reductions during sleep, a rapid rise upon
awakening, and increased variability during the awake period in ambulant normal subjects and
hypertensive patients.
Reduced diurnal systolic and diastolic BP pattern: nocturnal systolic and/or DBP fall from 1
to 10% of daytime values or night/day systolic and/or diastolic BP ratio <1 and >0.9.
Nocturnal HTN: increased absolute level of night time systolic and/or diastolic BP (≥120/70
mmHg).19 Dipping pattern is defined as daytime-nighttime BP/daytime BP reduction - based on
either ABP or home BP (HBP) monitoring- greater than 10% for systolic and/or diastolic BP.
Nighttime HTN is defined as nighttime ABP or HBP ≥125/75 mmHg (systolic and/or diastolic).
Non-dipping and rising: no reduction or increase in nocturnal systolic and/or diastolic BP
or night/day systolic and/or diastolic BP ratio ≥1.
Extreme dipping: marked nocturnal systolic and/or diastolic BP fall>20% of daytime systolic
and/or diastolic values or night/day systolic and/or diastolic BP ratio <0.8.
Morning surge: excessive systolic and/or diastolic BP elevation rising in the morning.
Secondary endpoints
- To detect asymptomatic and intermittent AF using a 24h ABPM with atrial fibrillation
detector device and to compare its accuracy with Holter monitoring.
- To investigate the agreement in the detection of paroxysmal AF using simultaneously the
24h-ABP with AF detection device and loop recording.
- To observe at which level of TOD, asymptomatic AF episodes are more commonly detected.
- To study if there is any relationship between systolic and/or diastolic BP levels with
AF occurrence.
- To examine whether office HR or mean HR using ABPM is associated with the development
of silent AF episodes.
- To examine whether a wide PP in ABPM is associated with the development of silent AF
episodes.
Variables used to determine the primary and secondary endpoints
- Sociodemographic data (birth date, gender, education level, employment status, place of
residence, smoking status/habits, alcohol consumption)
- Anthropometric characteristics (body weight, height, waist circumference)
- Any abnormal findings on physical examination
- Clinical relevant medical history and comorbidities
- Concomitant medications
- Electrocardiographic assessment
- Investigation of TOD, including echocardiography, carotid artery triplex, 24h-urine
albumin excretion and ABI
- Recent laboratory testing results including hemoglobin, hematocrit, blood glucose,
kidney and liver function tests
- Management of HTN (pharmacologic and non-pharmacologic treatment)
Inclusion Criteria
- Patients diagnosed with essential HTN (office BP>140/90mmHg) or patients receiving at
least one antihypertensive medication (ie. RAAA inhibitors or diuretic), aged 18-85
years of age.
- Patients with at least one of the following risk factors, organ damage or other
evidence of cardiovascular disease:
- Previous stroke
- Transient ischemic attack (TIA)
- Systemic embolism
- Diabetes mellitus type 2
- Obesity
- Obstructive sleep apnea (OSA)
- Dyslipidemia
- History of coronary artery disease (CAD)
- Valvular heart disease (VHD)
- Echocardiographic findings attributed to HTN (ie. diastolic dysfunction, LVH)
- White coat hypertension (WCH), masked hypertension (MH)
- Positive family history for rhythm disturbances
Exclusion Criteria
- Patients already diagnosed with paroxysmal or permanent AF
- Severe renal insufficiency (eGFR according to MDRD formula <25ml/min/1.73m2)
- Patients unable to attend follow-up visits
- Clinical evidence of severe heart failure
- Suspected secondary HTN
- Mental disorders
- Patients with cancer
The study protocol needs to be approved by the scientific board of the hospital and signed
informed consent needs to be obtained from all participants.
Study Design We are going to conduct a cross-sectional, observational study.
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Observational Model: Cohort, Time Perspective: Cross-Sectional